766-07-4

Basic information

• Product Name: cyclohexyl hydroperoxide
• Synonyms: cyclohexyl hydroperoxide;1α-Hydroperoxycyclohexane;1β-Hydroperoxycyclohexane;Hydroperoxycyclohexane
• CAS NO: 766-07-4
• Molecular Formula: C₆H₁₂O₂
• Molecular Weight: 116.15828
• EINECS: 212-159-5
• Mol File: 766-07-4.mol
• Article Data: 133

Chemical Properties

• Melting Point: -20°C
• Boiling Point: 216.85°C (estimate)
• Flash Point: 74.8°C
• Appearance: /
• Density: 1.0150
• Vapor Pressure: 0.0826mmHg at 25°C
• Refractive Index: 1.4638 (estimate)
• CAS DataBase Reference: cyclohexyl hydroperoxide(CAS DataBase Reference)
• NIST Chemistry Reference: cyclohexyl hydroperoxide(766-07-4)
• EPA Substance Registry System: cyclohexyl hydroperoxide(766-07-4)

Safety Data

• Hazardous Substances Data: 766-07-4(Hazardous Substances Data)

Usage

Synthesis Reference(s)

Journal of the American Chemical Society, 93, p. 4078, 1971 DOI: 10.1021/ja00745a060Tetrahedron, 43, p. 4059, 1987

InChI:InChI=1/C6H12O2/c7-8-6-4-2-1-3-5-6/h6-7H,1-5H2

Upstream product

• 110-82-7 cyclohexane 
• 1088-01-3 tricyclohexylborane 
• 10191-41-0 (+/-)-α-tocopherol 
• 39105-81-2 (dichloro)(cyclohexyl)borane 
• 119-13-1 dl-δ-tocopherol 
• 626-62-0 Cyclohexyl iodide 
• 16156-56-2 cyclohexyl mesylate 
• 108-85-0 1-bromocyclohexane 
• 7664-93-9 sulfuric acid 
• 7722-84-1 dihydrogen peroxide 
• 1600-27-7 mercury(II) diacetate 
• 2143-59-1 Cyclohexylperoxy radical 
• 75-91-2 tert.-butylhydroperoxide 
• 108-93-0 cyclohexanol 

Downstream Products

• 16980-60-2 1,4-Dimethyl-cyclohexanol 
• 16980-61-3 trans-1,4-dimethylcyclohexan-1-ol 
• 108-94-1 cyclohexanone 
• 108-93-0 cyclohexanol 
• 124-04-9 Adipic acid 
• 286-20-4 cyclohexane-1,2-epoxide 
• 110-94-1 1,5-pentanedioic acid 
• 110-15-6 succinic acid 
• 78-18-2 1-hydroxycyclohexyl 1-hydroperoxycyclohexyl peroxide 
• 2407-94-5 1,1'-dihydroxycyclohexyl peroxide 
• 2699-12-9 bis-(1-hydroperoxycyclohexyl)peroxide 
• 98-55-5 terpineol 
• 473-54-1 pinan-2α-ol 
• 473-54-1 cis-pinane-2-ol 

Relevant articles and documents

Decamethylosmocene-catalyzed efficient oxidation of saturated and aromatic hydrocarbons and alcohols with hydrogen peroxide in the presence of pyridine

Decamethylosmocene, (Me5C5)2Os (1), is a pre-catalyst in a very efficient oxidation of alkanes with hydrogen peroxide in acetonitrile at 20-60 °C. The reaction proceeds with a substantial lag period that can be reduced by the addition of pyridine in a small concentration. The lag period can be removed if 1 is incubated with pyridine and/or H 2O2 in MeCN prior to the alkane oxidation. Alkanes, RH, are oxidized primarily to the corresponding alkyl hydroperoxides, ROOH. Turnover numbers attain 51,000 in the case of cyclohexane (maximum turnover frequency was 6000 h-1) and 3600 in the case of ethane. The oxidation of benzene and styrene also occurs with a lag period to afford phenol and benzaldehyde, respectively. A kinetic study of cyclohexane oxidation and selectivity parameters (measured in the oxidation of n-heptane, methylcyclohexane, isooctane, cis- and trans-dimethylcyclohexanes) indicates that the oxidation of saturated, olefinic, and aromatic hydrocarbons proceeds with the participation of hydroxyl radicals. The 1/H2O 2/py/MeCN system also oxidizes 1-phenylethanol to acetophenone.

Vanadium(IV) complexes with picolinic acids in NaY zeolite cages: Synthesis, characterization and catalytic behaviour

Encapsulated vanadium picolinic complexes have been synthesized by treatment of a dehydrated form of VO2+-NaY zeolite with molten picolinic acids and characterized by X-ray photoelectron spectroscopy (XPS), extended X-ray absorption fine structure (EXAFS), X-ray absorption near-edge structure (XANES), EPR, FTIR and UV-VIS spectroscopies, and XRD. It was suggested by XRD and XPS that the complexes were located in the zeolite cavities. Differences in the spectroscopic properties of encapsulated and impregnated samples were explained in terms of coordination of vanadium complexes with zeolite -OH groups. The stability of VO(pic)2 and its adduct with pyridine depended strongly on the complex location. The encapsulated vanadium picolinate complex retained solution-like activity in the liquid-phase oxidation of hydrocarbons and alcohols with hydrogen peroxide.

Efficient oxidation of cycloalkanes with simultaneously increased conversion and selectivity using O2 catalyzed by metalloporphyrins and boosted by Zn(AcO)2: A practical strategy to inhibit the formation of aliphatic diacids

The direct sources of aliphatic acids in cycloalkanes oxidation were investigated, and a strategy to suppress the formation of aliphatic acids was adopted through enhancing the catalytic transformation of oxidation intermediates cycloalkyl hydroperoxides to cycloalkanols by Zn(II) and delaying the emergence of cycloalkanones. Benefitted from the delayed formation of cycloalkanones and suppressed non-selective thermal decomposition of cycloalkyl hydroperoxides, the conversion of cycloalkanes and selectivity towards cycloalkanols and cycloalkanones were increased simultaneously with satisfying tolerance to both of metalloporphyrins and substrates. For cyclohexane, the selectivity towards KA-oil was increased from 80.1% to 96.9% meanwhile the conversion was increased from 3.83 % to 6.53 %, a very competitive conversion level with higher selectivity compared with current industrial process. This protocol is not only a valuable strategy to overcome the problems of low conversion and low selectivity lying in front of current cyclohexane oxidation in industry, but also an important reference to other alkanes oxidation.

Facile Peroxidation of Cyclohexane Catalysed by In Situ Generated Triazole-Functionalised Schiff Base Copper Complexes

A set of facile room temperature catalytic systems for the oxidation of cyclohexane C–H bonds was developed from in situ generated triazole-functionalised Schiff base copper complexes. The combination of a new triazolium-functionalised Schiff base, [(E)-3-methyl-1-propyl-4-(2-(((2-(pyridin-2-yl)ethyl)imino)methyl)phenyl)-1H-1,2,3-triazol-3-ium hexafluorophosphate(V), 2] with a range of bench-top Cu(I) and Cu(II) salts (Cu2O, CuO, Cu(CH3CN)4PF6, CuSO4·5H2O, Cu2(OAc)4·2H2O, CuCl2, Cu(NO3)2·3H2O) as catalysts were screened under varying reaction conditions for the peroxidation of cyclohexane using hydrogen peroxide as a green source of oxygen. High conversions to oxidised products were obtained with up to 80% in 6?h for the 2/CuSO4·5H2O system at 1?mol% catalyst concentration under optimised reaction conditions. All the copper salts yielded the ketone–alcohol (K–A) oil containing varying ratios of cyclohexanol and cyclohexanone. The results also showed that at room temperature, the various in situ generated copper catalysts exclusively yielded only the K–A oil. Furthermore, by changing the reaction temperature to reflux in acetonitrile and depending on the starting substrate (cyclohexane, cyclohexanol or cyclohexanone), 23–100% of adipic acid was also obtained. The kinetics study for the peroxidation reaction reveals activation energy of 12.29 ± 2?kJ/mol following a copper initiated radical mechanism. Graphic Abstract: [Figure not available: see fulltext.]

Confinement porphyrin Co (II), and preparation method and application thereof

Confinement porphyrin Co (II). A preparation method includes: under acidic condition, performing condensation on aromatic aldehyde and pyrrole in equal molar ratio to obtain a phenylporphyrin compound, and carrying out metallization in a chloroform-methanol solution to obtain porphyrin Cu (II), performing bromination and demetalization by perchloric acid to obtain confinement porphyrin, performingstirring reflux on the confinement porphyrin in a methanol solution for 12.0-24.0 h to obtain confinement porphyrin Co (II). An application includes: dissolving the confinement porphyrin Co (II) in naphthenic hydrocarbon and sealing the reaction system, stirring and heating the reaction system to 100-130 DEG C and feeding oxygen to 0.2-3.0 MPa; maintaining the set temperature and oxygen pressureand performing a stirring reaction for 3.0-24.0 h; performing after treatment on the reaction liquid to prepare the product. In the invention, generation of fatty diacid is effectively inhibited, andcontinuity of a naphthenic hydrocarbon oxidization process and product separation is facilitated. The invention has the potential of solving the problem that naphthene alcohols and naphthene ketones are liable to undergo deep oxidization and form the fatty diacid in an industrial naphthenic hydrocarbon catalytic oxidation process.